/* * Copyright (C) 2007-2009 Gabest * http://www.gabest.org * * This Program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2, or (at your option) * any later version. * * This Program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GNU Make; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA USA. * http://www.gnu.org/copyleft/gpl.html * */ #include "stdafx.h" #include "GSdx.h" #include "GSUtil.h" #include "Renderers/SW/GSRendererSW.h" #include "Renderers/Null/GSRendererNull.h" #include "Renderers/Null/GSDeviceNull.h" #include "Renderers/OpenGL/GSDeviceOGL.h" #include "Renderers/OpenGL/GSRendererOGL.h" #include "GSLzma.h" #ifdef _WIN32 #include "Renderers/DX11/GSRendererDX11.h" #include "Renderers/DX11/GSDevice11.h" #include "Window/GSWndDX.h" #include "Window/GSWndWGL.h" #include "Window/GSSettingsDlg.h" static HRESULT s_hr = E_FAIL; #else #include "Window/GSWndEGL.h" extern bool RunLinuxDialog(); #endif #define PS2E_LT_GS 0x01 #define PS2E_GS_VERSION 0x0006 #define PS2E_X86 0x01 // 32 bit #define PS2E_X86_64 0x02 // 64 bit static GSRenderer* s_gs = NULL; static void (*s_irq)() = NULL; static uint8* s_basemem = NULL; static int s_vsync = 0; static bool s_exclusive = true; static std::string s_renderer_name; bool gsopen_done = false; // crash guard for GSgetTitleInfo2 and GSKeyEvent (replace with lock?) EXPORT_C_(uint32) PS2EgetLibType() { return PS2E_LT_GS; } EXPORT_C_(const char*) PS2EgetLibName() { return GSUtil::GetLibName(); } EXPORT_C_(uint32) PS2EgetLibVersion2(uint32 type) { const uint32 revision = 1; const uint32 build = 2; return (build << 0) | (revision << 8) | (PS2E_GS_VERSION << 16) | (PLUGIN_VERSION << 24); } EXPORT_C_(uint32) PS2EgetCpuPlatform() { #ifdef _M_AMD64 return PS2E_X86_64; #else return PS2E_X86; #endif } EXPORT_C GSsetBaseMem(uint8* mem) { s_basemem = mem; if(s_gs) { s_gs->SetRegsMem(s_basemem); } } EXPORT_C GSsetSettingsDir(const char* dir) { theApp.SetConfigDir(dir); } EXPORT_C_(int) GSinit() { if(!GSUtil::CheckSSE()) { return -1; } // Vector instructions must be avoided when initialising GSdx since PCSX2 // can crash if the CPU does not support the instruction set. // Initialise it here instead - it's not ideal since we have to strip the // const type qualifier from all the affected variables. theApp.Init(); GSUtil::Init(); GSBlock::InitVectors(); GSClut::InitVectors(); GSRendererSW::InitVectors(); GSVector4i::InitVectors(); GSVector4::InitVectors(); #if _M_SSE >= 0x500 GSVector8::InitVectors(); #endif #if _M_SSE >= 0x501 GSVector8i::InitVectors(); #endif GSVertexTrace::InitVectors(); if (g_const == nullptr) return -1; else g_const->Init(); #ifdef _WIN32 s_hr = ::CoInitializeEx(NULL, COINIT_MULTITHREADED); #endif return 0; } EXPORT_C GSshutdown() { gsopen_done = false; delete s_gs; s_gs = nullptr; theApp.SetCurrentRendererType(GSRendererType::Undefined); #ifdef _WIN32 if(SUCCEEDED(s_hr)) { ::CoUninitialize(); s_hr = E_FAIL; } #endif } EXPORT_C GSclose() { gsopen_done = false; if(s_gs == NULL) return; s_gs->ResetDevice(); // Opengl requirement: It must be done before the Detach() of // the context delete s_gs->m_dev; s_gs->m_dev = NULL; if (s_gs->m_wnd) { s_gs->m_wnd->Detach(); } } static int _GSopen(void** dsp, const char* title, GSRendererType renderer, int threads = -1) { GSDevice* dev = NULL; bool old_api = *dsp == NULL; // Fresh start up or config file changed if(renderer == GSRendererType::Undefined) { renderer = static_cast(theApp.GetConfigI("Renderer")); #ifdef _WIN32 if (renderer == GSRendererType::Default) renderer = GSUtil::GetBestRenderer(); #endif } if(threads == -1) { threads = theApp.GetConfigI("extrathreads"); } try { if (theApp.GetCurrentRendererType() != renderer) { // Emulator has made a render change request, which requires a completely // new s_gs -- if the emu doesn't save/restore the GS state across this // GSopen call then they'll get corrupted graphics, but that's not my problem. delete s_gs; s_gs = NULL; theApp.SetCurrentRendererType(renderer); } std::shared_ptr window; { // Select the window first to detect the GL requirement std::vector> wnds; switch (renderer) { case GSRendererType::OGL_HW: case GSRendererType::OGL_SW: #if defined(__unix__) // Note: EGL code use GLX otherwise maybe it could be also compatible with Windows // Yes OpenGL code isn't complicated enough ! switch (GSWndEGL::SelectPlatform()) { #if GS_EGL_X11 case EGL_PLATFORM_X11_KHR: wnds.push_back(std::make_shared()); break; #endif #if GS_EGL_WL case EGL_PLATFORM_WAYLAND_KHR: wnds.push_back(std::make_shared()); break; #endif default: break; } #else wnds.push_back(std::make_shared()); #endif break; default: #ifdef _WIN32 wnds.push_back(std::make_shared()); #else wnds.push_back(std::make_shared()); #endif break; } int w = theApp.GetConfigI("ModeWidth"); int h = theApp.GetConfigI("ModeHeight"); #if defined(__unix__) void *win_handle = (void*)((uptr*)(dsp)+1); #else void *win_handle = *dsp; #endif for(auto& wnd : wnds) { try { if (old_api) { // old-style API expects us to create and manage our own window: wnd->Create(title, w, h); wnd->Show(); *dsp = wnd->GetDisplay(); } else { wnd->Attach(win_handle, false); } window = wnd; // Previous code will throw if window isn't supported break; } catch (GSDXRecoverableError) { wnd->Detach(); } } if(!window) { GSclose(); return -1; } } std::string renderer_name; switch (renderer) { default: #ifdef _WIN32 case GSRendererType::DX1011_HW: dev = new GSDevice11(); s_renderer_name = "D3D11"; renderer_name = "Direct3D 11"; break; #endif case GSRendererType::OGL_HW: dev = new GSDeviceOGL(); s_renderer_name = "OGL"; renderer_name = "OpenGL"; break; case GSRendererType::OGL_SW: dev = new GSDeviceOGL(); s_renderer_name = "SW"; renderer_name = "Software"; break; case GSRendererType::Null: dev = new GSDeviceNull(); s_renderer_name = "NULL"; renderer_name = "Null"; break; } printf("Current Renderer: %s\n", renderer_name.c_str()); if (dev == NULL) { return -1; } if (s_gs == NULL) { switch (renderer) { default: #ifdef _WIN32 case GSRendererType::DX1011_HW: s_gs = (GSRenderer*)new GSRendererDX11(); break; #endif case GSRendererType::OGL_HW: s_gs = (GSRenderer*)new GSRendererOGL(); break; case GSRendererType::OGL_SW: s_gs = new GSRendererSW(threads); break; case GSRendererType::Null: s_gs = new GSRendererNull(); break; } if (s_gs == NULL) return -1; } s_gs->m_wnd = window; } catch (std::exception& ex) { // Allowing std exceptions to escape the scope of the plugin callstack could // be problematic, because of differing typeids between DLL and EXE compilations. // ('new' could throw std::alloc) printf("GSdx error: Exception caught in GSopen: %s", ex.what()); return -1; } s_gs->SetRegsMem(s_basemem); s_gs->SetIrqCallback(s_irq); s_gs->SetVSync(s_vsync); if(!old_api) s_gs->SetMultithreaded(true); if(!s_gs->CreateDevice(dev)) { // This probably means the user has DX11 configured with a video card that is only DX9 // compliant. Cound mean drivr issues of some sort also, but to be sure, that's the most // common cause of device creation errors. :) --air GSclose(); return -1; } if (renderer == GSRendererType::OGL_HW && theApp.GetConfigI("debug_glsl_shader") == 2) { printf("GSdx: test OpenGL shader. Please wait...\n\n"); static_cast(s_gs->m_dev)->SelfShaderTest(); printf("\nGSdx: test OpenGL shader done. It will now exit\n"); return -1; } return 0; } EXPORT_C_(void) GSosdLog(const char *utf8, uint32 color) { if(s_gs && s_gs->m_dev) s_gs->m_dev->m_osd.Log(utf8); } EXPORT_C_(void) GSosdMonitor(const char *key, const char *value, uint32 color) { if(s_gs && s_gs->m_dev) s_gs->m_dev->m_osd.Monitor(key, value); } EXPORT_C_(int) GSopen2(void** dsp, uint32 flags) { static bool stored_toggle_state = false; const bool toggle_state = !!(flags & 4); auto current_renderer = theApp.GetCurrentRendererType(); if (current_renderer != GSRendererType::Undefined && stored_toggle_state != toggle_state) { // SW -> HW and HW -> SW (F9 Switch) switch (current_renderer) { #ifdef _WIN32 case GSRendererType::DX1011_HW: current_renderer = GSRendererType::OGL_SW; break; #endif case GSRendererType::OGL_SW: #ifdef _WIN32 { const auto config_renderer = static_cast( theApp.GetConfigI("Renderer") ); if (current_renderer == config_renderer) current_renderer = GSUtil::GetBestRenderer(); else current_renderer = config_renderer; } #else current_renderer = GSRendererType::OGL_HW; #endif break; case GSRendererType::OGL_HW: current_renderer = GSRendererType::OGL_SW; break; default: current_renderer = GSRendererType::OGL_SW; break; } } stored_toggle_state = toggle_state; int retval = _GSopen(dsp, "", current_renderer); if (s_gs != NULL) s_gs->SetAspectRatio(0); // PCSX2 manages the aspect ratios gsopen_done = true; return retval; } EXPORT_C_(int) GSopen(void** dsp, const char* title, int mt) { GSRendererType renderer = GSRendererType::Default; // Legacy GUI expects to acquire vsync from the configuration files. s_vsync = theApp.GetConfigI("vsync"); if(mt == 2) { // pcsx2 sent a switch renderer request mt = 1; } else { // normal init renderer = static_cast(theApp.GetConfigI("Renderer")); } *dsp = NULL; int retval = _GSopen(dsp, title, renderer); if(retval == 0 && s_gs) { s_gs->SetMultithreaded(!!mt); } gsopen_done = true; return retval; } EXPORT_C GSreset() { try { s_gs->Reset(); } catch (GSDXRecoverableError) { } } EXPORT_C GSgifSoftReset(uint32 mask) { try { s_gs->SoftReset(mask); } catch (GSDXRecoverableError) { } } EXPORT_C GSwriteCSR(uint32 csr) { try { s_gs->WriteCSR(csr); } catch (GSDXRecoverableError) { } } EXPORT_C GSinitReadFIFO(uint8* mem) { GL_PERF("Init Read FIFO1"); try { s_gs->InitReadFIFO(mem, 1); } catch (GSDXRecoverableError) { } catch (const std::bad_alloc&) { fprintf(stderr, "GSdx: Memory allocation error\n"); } } EXPORT_C GSreadFIFO(uint8* mem) { try { s_gs->ReadFIFO(mem, 1); } catch (GSDXRecoverableError) { } catch (const std::bad_alloc&) { fprintf(stderr, "GSdx: Memory allocation error\n"); } } EXPORT_C GSinitReadFIFO2(uint8* mem, uint32 size) { GL_PERF("Init Read FIFO2"); try { s_gs->InitReadFIFO(mem, size); } catch (GSDXRecoverableError) { } catch (const std::bad_alloc&) { fprintf(stderr, "GSdx: Memory allocation error\n"); } } EXPORT_C GSreadFIFO2(uint8* mem, uint32 size) { try { s_gs->ReadFIFO(mem, size); } catch (GSDXRecoverableError) { } catch (const std::bad_alloc&) { fprintf(stderr, "GSdx: Memory allocation error\n"); } } EXPORT_C GSgifTransfer(const uint8* mem, uint32 size) { try { s_gs->Transfer<3>(mem, size); } catch (GSDXRecoverableError) { } } EXPORT_C GSgifTransfer1(uint8* mem, uint32 addr) { try { s_gs->Transfer<0>(const_cast(mem) + addr, (0x4000 - addr) / 16); } catch (GSDXRecoverableError) { } } EXPORT_C GSgifTransfer2(uint8* mem, uint32 size) { try { s_gs->Transfer<1>(const_cast(mem), size); } catch (GSDXRecoverableError) { } } EXPORT_C GSgifTransfer3(uint8* mem, uint32 size) { try { s_gs->Transfer<2>(const_cast(mem), size); } catch (GSDXRecoverableError) { } } EXPORT_C GSvsync(int field) { try { #ifdef _WIN32 if(s_gs->m_wnd->IsManaged()) { MSG msg; memset(&msg, 0, sizeof(msg)); while(msg.message != WM_QUIT && PeekMessage(&msg, NULL, 0, 0, PM_REMOVE)) { TranslateMessage(&msg); DispatchMessage(&msg); } } #endif s_gs->VSync(field); } catch (GSDXRecoverableError) { } catch (const std::bad_alloc&) { fprintf(stderr, "GSdx: Memory allocation error\n"); } } EXPORT_C_(uint32) GSmakeSnapshot(char* path) { try { std::string s{path}; if (!s.empty()) { // Allows for providing a complete path std::string extension = s.substr(s.size() - 4, 4); std::transform(extension.begin(), extension.end(), extension.begin(), tolower); if (extension == ".png") return s_gs->MakeSnapshot(s); else if (s[s.length() - 1] != DIRECTORY_SEPARATOR) s = s + DIRECTORY_SEPARATOR; } return s_gs->MakeSnapshot(s + "gsdx"); } catch (GSDXRecoverableError) { return false; } } EXPORT_C GSkeyEvent(GSKeyEventData* e) { try { if(gsopen_done) { s_gs->KeyEvent(e); } } catch (GSDXRecoverableError) { } } EXPORT_C_(int) GSfreeze(int mode, GSFreezeData* data) { try { if(mode == FREEZE_SAVE) { return s_gs->Freeze(data, false); } else if(mode == FREEZE_SIZE) { return s_gs->Freeze(data, true); } else if(mode == FREEZE_LOAD) { return s_gs->Defrost(data); } } catch (GSDXRecoverableError) { } return 0; } EXPORT_C GSconfigure() { try { if(!GSUtil::CheckSSE()) return; theApp.Init(); #ifdef _WIN32 GSDialog::InitCommonControls(); if(GSSettingsDlg().DoModal() == IDOK) { // Force a reload of the gs state theApp.SetCurrentRendererType(GSRendererType::Undefined); } #else if (RunLinuxDialog()) { theApp.ReloadConfig(); // Force a reload of the gs state theApp.SetCurrentRendererType(GSRendererType::Undefined); } #endif } catch (GSDXRecoverableError) { } } EXPORT_C_(int) GStest() { if(!GSUtil::CheckSSE()) return -1; return 0; } EXPORT_C GSabout() { } EXPORT_C GSirqCallback(void (*irq)()) { s_irq = irq; if(s_gs) { s_gs->SetIrqCallback(s_irq); } } void pt(const char* str){ struct tm *current; time_t now; time(&now); current = localtime(&now); printf("%02i:%02i:%02i%s", current->tm_hour, current->tm_min, current->tm_sec, str); } EXPORT_C_(std::wstring*) GSsetupRecording(int start) { if (s_gs == NULL) { printf("GSdx: no s_gs for recording\n"); return nullptr; } #if defined(__unix__) if (!theApp.GetConfigB("capture_enabled")) { printf("GSdx: Recording is disabled\n"); return nullptr; } #endif std::wstring* filename = nullptr; if(start & 1) { printf("GSdx: Recording start command\n"); filename = s_gs->BeginCapture(); if (filename) { pt(" - Capture started\n"); } else { pt(" - Capture cancelled\n"); return nullptr; } } else { printf("GSdx: Recording end command\n"); s_gs->EndCapture(); pt(" - Capture ended\n"); } return filename; } EXPORT_C GSsetGameCRC(uint32 crc, int options) { s_gs->SetGameCRC(crc, options); } EXPORT_C GSgetLastTag(uint32* tag) { s_gs->GetLastTag(tag); } EXPORT_C GSgetTitleInfo2(char* dest, size_t length) { std::string s; s.append(s_renderer_name); // TODO: this gets called from a different thread concurrently with GSOpen (on linux) if (gsopen_done && s_gs != NULL && s_gs->m_GStitleInfoBuffer[0]) { std::lock_guard lock(s_gs->m_pGSsetTitle_Crit); s.append(" | ").append(s_gs->m_GStitleInfoBuffer); if(s.size() > length - 1) { s = s.substr(0, length - 1); } } strcpy(dest, s.c_str()); } EXPORT_C GSsetFrameSkip(int frameskip) { s_gs->SetFrameSkip(frameskip); } EXPORT_C GSsetVsync(int vsync) { s_vsync = vsync; if(s_gs) { s_gs->SetVSync(s_vsync); } } EXPORT_C GSsetExclusive(int enabled) { s_exclusive = !!enabled; if(s_gs) { s_gs->SetVSync(s_vsync); } } #ifdef _WIN32 #include #include class Console { HANDLE m_console; std::string m_title; public: Console::Console(LPCSTR title, bool open) : m_console(NULL) , m_title(title) { if(open) Open(); } Console::~Console() { Close(); } void Console::Open() { if(m_console == NULL) { CONSOLE_SCREEN_BUFFER_INFO csbiInfo; AllocConsole(); SetConsoleTitle(m_title.c_str()); m_console = GetStdHandle(STD_OUTPUT_HANDLE); COORD size; size.X = 100; size.Y = 300; SetConsoleScreenBufferSize(m_console, size); GetConsoleScreenBufferInfo(m_console, &csbiInfo); SMALL_RECT rect; rect = csbiInfo.srWindow; rect.Right = rect.Left + 99; rect.Bottom = rect.Top + 64; SetConsoleWindowInfo(m_console, TRUE, &rect); freopen("CONOUT$", "w", stdout); freopen("CONOUT$", "w", stderr); setvbuf(stdout, nullptr, _IONBF, 0); setvbuf(stderr, nullptr, _IONBF, 0); } } void Console::Close() { if(m_console != NULL) { FreeConsole(); m_console = NULL; } } }; // lpszCmdLine: // First parameter is the renderer. // Second parameter is the gs file to load and run. EXPORT_C GSReplay(HWND hwnd, HINSTANCE hinst, LPSTR lpszCmdLine, int nCmdShow) { GSRendererType renderer = GSRendererType::Undefined; { char* start = lpszCmdLine; char* end = NULL; long n = strtol(lpszCmdLine, &end, 10); if(end > start) {renderer = static_cast(n); lpszCmdLine = end;} } while(*lpszCmdLine == ' ') lpszCmdLine++; ::SetPriorityClass(::GetCurrentProcess(), HIGH_PRIORITY_CLASS); Console console{"GSdx", true}; const std::string f{lpszCmdLine}; const bool is_xz = f.size() >= 4 && f.compare(f.size() - 3, 3, ".xz") == 0; auto file = is_xz ? std::unique_ptr{std::make_unique(lpszCmdLine, nullptr)} : std::unique_ptr{std::make_unique(lpszCmdLine, nullptr)}; GSinit(); std::array regs; GSsetBaseMem(regs.data()); s_vsync = theApp.GetConfigI("vsync"); HWND hWnd = nullptr; _GSopen((void**)&hWnd, "", renderer); uint32 crc; file->Read(&crc, 4); GSsetGameCRC(crc, 0); { GSFreezeData fd; file->Read(&fd.size, 4); std::vector freeze_data(fd.size); fd.data = freeze_data.data(); file->Read(fd.data, fd.size); GSfreeze(FREEZE_LOAD, &fd); } file->Read(regs.data(), 0x2000); GSvsync(1); struct Packet {uint8 type, param; uint32 size, addr; std::vector buff;}; auto read_packet = [&file](uint8 type) { Packet p; p.type = type; switch(p.type) { case 0: file->Read(&p.param, 1); file->Read(&p.size, 4); switch(p.param) { case 0: p.buff.resize(0x4000); p.addr = 0x4000 - p.size; file->Read(&p.buff[p.addr], p.size); break; case 1: case 2: case 3: p.buff.resize(p.size); file->Read(p.buff.data(), p.size); break; } break; case 1: file->Read(&p.param, 1); break; case 2: file->Read(&p.size, 4); break; case 3: p.buff.resize(0x2000); file->Read(p.buff.data(), 0x2000); break; } return p; }; std::list packets; uint8 type; while(file->Read(&type, 1)) packets.push_back(read_packet(type)); Sleep(100); std::vector buff; while(IsWindowVisible(hWnd)) { for(auto &p : packets) { switch(p.type) { case 0: switch(p.param) { case 0: GSgifTransfer1(p.buff.data(), p.addr); break; case 1: GSgifTransfer2(p.buff.data(), p.size / 16); break; case 2: GSgifTransfer3(p.buff.data(), p.size / 16); break; case 3: GSgifTransfer(p.buff.data(), p.size / 16); break; } break; case 1: GSvsync(p.param); break; case 2: if(buff.size() < p.size) buff.resize(p.size); GSreadFIFO2(p.buff.data(), p.size / 16); break; case 3: memcpy(regs.data(), p.buff.data(), 0x2000); break; } } } Sleep(100); GSclose(); GSshutdown(); } EXPORT_C GSBenchmark(HWND hwnd, HINSTANCE hinst, LPSTR lpszCmdLine, int nCmdShow) { ::SetPriorityClass(::GetCurrentProcess(), HIGH_PRIORITY_CLASS); Console console("GSdx", true); if(1) { GSLocalMemory* mem = new GSLocalMemory(); static struct {int psm; const char* name;} s_format[] = { {PSM_PSMCT32, "32"}, {PSM_PSMCT24, "24"}, {PSM_PSMCT16, "16"}, {PSM_PSMCT16S, "16S"}, {PSM_PSMT8, "8"}, {PSM_PSMT4, "4"}, {PSM_PSMT8H, "8H"}, {PSM_PSMT4HL, "4HL"}, {PSM_PSMT4HH, "4HH"}, {PSM_PSMZ32, "32Z"}, {PSM_PSMZ24, "24Z"}, {PSM_PSMZ16, "16Z"}, {PSM_PSMZ16S, "16ZS"}, }; uint8* ptr = (uint8*)_aligned_malloc(1024 * 1024 * 4, 32); for(int i = 0; i < 1024 * 1024 * 4; i++) ptr[i] = (uint8)i; // for(int tbw = 5; tbw <= 10; tbw++) { int n = 256 << ((10 - tbw) * 2); int w = 1 << tbw; int h = 1 << tbw; printf("%d x %d\n\n", w, h); for(size_t i = 0; i < countof(s_format); i++) { const GSLocalMemory::psm_t& psm = GSLocalMemory::m_psm[s_format[i].psm]; GSLocalMemory::writeImage wi = psm.wi; GSLocalMemory::readImage ri = psm.ri; GSLocalMemory::readTexture rtx = psm.rtx; GSLocalMemory::readTexture rtxP = psm.rtxP; GIFRegBITBLTBUF BITBLTBUF; BITBLTBUF.SBP = 0; BITBLTBUF.SBW = w / 64; BITBLTBUF.SPSM = s_format[i].psm; BITBLTBUF.DBP = 0; BITBLTBUF.DBW = w / 64; BITBLTBUF.DPSM = s_format[i].psm; GIFRegTRXPOS TRXPOS; TRXPOS.SSAX = 0; TRXPOS.SSAY = 0; TRXPOS.DSAX = 0; TRXPOS.DSAY = 0; GIFRegTRXREG TRXREG; TRXREG.RRW = w; TRXREG.RRH = h; GSVector4i r(0, 0, w, h); GIFRegTEX0 TEX0; TEX0.TBP0 = 0; TEX0.TBW = w / 64; GIFRegTEXA TEXA; TEXA.TA0 = 0; TEXA.TA1 = 0x80; TEXA.AEM = 0; int trlen = w * h * psm.trbpp / 8; int len = w * h * psm.bpp / 8; clock_t start, end; printf("[%4s] ", s_format[i].name); start = clock(); for(int j = 0; j < n; j++) { int x = 0; int y = 0; (mem->*wi)(x, y, ptr, trlen, BITBLTBUF, TRXPOS, TRXREG); } end = clock(); printf("%6d %6d | ", (int)((float)trlen * n / (end - start) / 1000), (int)((float)(w * h) * n / (end - start) / 1000)); start = clock(); for(int j = 0; j < n; j++) { int x = 0; int y = 0; (mem->*ri)(x, y, ptr, trlen, BITBLTBUF, TRXPOS, TRXREG); } end = clock(); printf("%6d %6d | ", (int)((float)trlen * n / (end - start) / 1000), (int)((float)(w * h) * n / (end - start) / 1000)); const GSOffset* off = mem->GetOffset(TEX0.TBP0, TEX0.TBW, TEX0.PSM); start = clock(); for(int j = 0; j < n; j++) { (mem->*rtx)(off, r, ptr, w * 4, TEXA); } end = clock(); printf("%6d %6d ", (int)((float)len * n / (end - start) / 1000), (int)((float)(w * h) * n / (end - start) / 1000)); if(psm.pal > 0) { start = clock(); for(int j = 0; j < n; j++) { (mem->*rtxP)(off, r, ptr, w, TEXA); } end = clock(); printf("| %6d %6d ", (int)((float)len * n / (end - start) / 1000), (int)((float)(w * h) * n / (end - start) / 1000)); } printf("\n"); } printf("\n"); } _aligned_free(ptr); delete mem; } // if(0) { GSLocalMemory* mem = new GSLocalMemory(); uint8* ptr = (uint8*)_aligned_malloc(1024 * 1024 * 4, 32); for(int i = 0; i < 1024 * 1024 * 4; i++) ptr[i] = (uint8)i; const GSLocalMemory::psm_t& psm = GSLocalMemory::m_psm[PSM_PSMCT32]; GSLocalMemory::writeImage wi = psm.wi; GIFRegBITBLTBUF BITBLTBUF; BITBLTBUF.DBP = 0; BITBLTBUF.DBW = 32; BITBLTBUF.DPSM = PSM_PSMCT32; GIFRegTRXPOS TRXPOS; TRXPOS.DSAX = 0; TRXPOS.DSAY = 1; GIFRegTRXREG TRXREG; TRXREG.RRW = 256; TRXREG.RRH = 256; int trlen = 256 * 256 * psm.trbpp / 8; int x = 0; int y = 0; (mem->*wi)(x, y, ptr, trlen, BITBLTBUF, TRXPOS, TRXREG); delete mem; } // PostQuitMessage(0); } #endif #if defined(__unix__) inline unsigned long timeGetTime() { struct timespec t; clock_gettime(CLOCK_REALTIME, &t); return (unsigned long)(t.tv_sec*1000 + t.tv_nsec/1000000); } // Note EXPORT_C GSReplay(char* lpszCmdLine, int renderer) { GLLoader::in_replayer = true; // Required by multithread driver XInitThreads(); GSinit(); GSRendererType m_renderer; // Allow to easyly switch between SW/HW renderer -> this effectively removes the ability to select the renderer by function args m_renderer = static_cast(theApp.GetConfigI("Renderer")); if (m_renderer != GSRendererType::OGL_HW && m_renderer != GSRendererType::OGL_SW) { fprintf(stderr, "wrong renderer selected %d\n", static_cast(m_renderer)); return; } struct Packet {uint8 type, param; uint32 size, addr; std::vector buff;}; std::list packets; std::vector buff; uint8 regs[0x2000]; GSsetBaseMem(regs); s_vsync = theApp.GetConfigI("vsync"); int finished = theApp.GetConfigI("linux_replay"); bool repack_dump = (finished < 0); if (theApp.GetConfigI("dump")) { fprintf(stderr, "Dump is enabled. Replay will be disabled\n"); finished = 1; } long frame_number = 0; void* hWnd = NULL; int err = _GSopen((void**)&hWnd, "", m_renderer); if (err != 0) { fprintf(stderr, "Error failed to GSopen\n"); return; } if (s_gs->m_wnd == NULL) return; { // Read .gs content std::string f(lpszCmdLine); bool is_xz = (f.size() >= 4) && (f.compare(f.size()-3, 3, ".xz") == 0); if (is_xz) f.replace(f.end()-6, f.end(), "_repack.gs"); else f.replace(f.end()-3, f.end(), "_repack.gs"); GSDumpFile* file = is_xz ? (GSDumpFile*) new GSDumpLzma(lpszCmdLine, repack_dump ? f.c_str() : nullptr) : (GSDumpFile*) new GSDumpRaw(lpszCmdLine, repack_dump ? f.c_str() : nullptr); uint32 crc; file->Read(&crc, 4); GSsetGameCRC(crc, 0); GSFreezeData fd; file->Read(&fd.size, 4); fd.data = new uint8[fd.size]; file->Read(fd.data, fd.size); GSfreeze(FREEZE_LOAD, &fd); delete [] fd.data; file->Read(regs, 0x2000); uint8 type; while(file->Read(&type, 1)) { Packet* p = new Packet(); p->type = type; switch(type) { case 0: file->Read(&p->param, 1); file->Read(&p->size, 4); switch(p->param) { case 0: p->buff.resize(0x4000); p->addr = 0x4000 - p->size; file->Read(&p->buff[p->addr], p->size); break; case 1: case 2: case 3: p->buff.resize(p->size); file->Read(&p->buff[0], p->size); break; } break; case 1: file->Read(&p->param, 1); frame_number++; break; case 2: file->Read(&p->size, 4); break; case 3: p->buff.resize(0x2000); file->Read(&p->buff[0], 0x2000); break; } packets.push_back(p); if (repack_dump && frame_number > -finished) break; } delete file; } sleep(2); frame_number = 0; // Init vsync stuff GSvsync(1); while(finished > 0) { for(auto i = packets.begin(); i != packets.end(); i++) { Packet* p = *i; switch(p->type) { case 0: switch(p->param) { case 0: GSgifTransfer1(&p->buff[0], p->addr); break; case 1: GSgifTransfer2(&p->buff[0], p->size / 16); break; case 2: GSgifTransfer3(&p->buff[0], p->size / 16); break; case 3: GSgifTransfer(&p->buff[0], p->size / 16); break; } break; case 1: GSvsync(p->param); frame_number++; break; case 2: if(buff.size() < p->size) buff.resize(p->size); GSreadFIFO2(&buff[0], p->size / 16); break; case 3: memcpy(regs, &p->buff[0], 0x2000); break; } } if (finished >= 200) { ; // Nop for Nvidia Profiler } else if (finished > 90) { sleep(1); } else { finished--; } } static_cast(s_gs->m_dev)->GenerateProfilerData(); #ifdef ENABLE_OGL_DEBUG_MEM_BW unsigned long total_frame_nb = std::max(1l, frame_number) << 10; fprintf(stderr, "memory bandwith. T: %f KB/f. V: %f KB/f. U: %f KB/f\n", (float)g_real_texture_upload_byte/(float)total_frame_nb, (float)g_vertex_upload_byte/(float)total_frame_nb, (float)g_uniform_upload_byte/(float)total_frame_nb ); #endif for(auto i = packets.begin(); i != packets.end(); i++) { delete *i; } packets.clear(); sleep(2); GSclose(); GSshutdown(); } #endif